A and B are moving in two circular orbits with angular velocity
`2 omega and omega` respectively. Their position are shown at t = 0. Find the time at which they will meet for 1st time

Two discs A and B are in contact and rotating with angular velocity with angular velocities omega_(1) and omega_(2) respectively as shown. If there is no slipping between the discs, then

A particle moves in a circular path of radius R with an angualr velocity omega=a-bt , where a and b are positive constants and t is time. The magnitude of the acceleration of the particle after time (2a)/(b) is

A body of mass m is moving in a circle of radius angular velocity omega . Find the expression for centripetal force acting on it by the method of dimensions

Two particles A and B are moving in a horizontal plane anitclockwise on two different concentric circles with different constant angular velocities 2omega and omega respectively. Find the relative velocity (in m/s) of B w.r.t. A after tome t=pi//omega . They both start at the position as shown in figure ("Take" omega=3rad//sec, r=2m)

A conical pendulum is moving in a circle with angular velocity omega as shown. If tension in the string is T, which of following equations are correct ?

A partical excutes SHM with amplitude A and angular frequency omega . At an instant the particle is at a distance A//5 from the mean position and is moving away from it. Find the time after which it will come back to this position again and also find the time after which it will pass through the mean position.

Two objects A and B are moving in opposite directions with velocities v_(A) and v_(B) respectively, the magnitude of relative velocity of A w.r.t. B is

A uniform rod is hinged at its one end and is allowed to rotate in verticle plANE. Rod is given angular velocity omega in its verticle position as shown in figure. The value of omega for the force exerted by the hinge on rod is zero in this position is

Two particles having mass 'M' and 'm' are moving in a circular path having radius R & r respectively. If their time period are same then the ratio of angular velocity will be : -

A point charges Q is moving in a circular orbit of radius R in the x-y plane with an angular velocity omega . This can be considered as equivalent to a loop carrying a steady current (Q omega)/(2 pi) . S uniform magnetic field along the positive z-axis is now switched on, which increases at a constant rate from 0 to B in one second. Assume that the radius of hte orbit remains constant. The application of hte magnetic field induces an emf in the orbit. The induced emf is defined as the work done by an induced electric field in moving a unit positive charge around a closed loop. It si known that, for an orbiting charge, the magnetic dipole moment is proportional to the angular momentum with a porportionality constant lambda . The magnitude of the induced electric field in the orbit at any instant of time during the time interval of the mangnetic field change is